/**********************************************************************
 *
 * Name:     gdalvirtualmem.cpp
 * Project:  GDAL
 * Purpose:  Dataset and rasterband exposed as a virtual memory mapping.
 * Author:   Even Rouault, <even dot rouault at spatialys.com>
 *
 **********************************************************************
 * Copyright (c) 2014, Even Rouault <even dot rouault at spatialys.com>
 *
 * Permission is hereby granted, free of charge, to any person obtaining a
 * copy of this software and associated documentation files (the "Software"),
 * to deal in the Software without restriction, including without limitation
 * the rights to use, copy, modify, merge, publish, distribute, sublicense,
 * and/or sell copies of the Software, and to permit persons to whom the
 * Software is furnished to do so, subject to the following conditions:
 *
 * The above copyright notice and this permission notice shall be included
 * in all copies or substantial portions of the Software.
 *
 * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
 * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
 * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.  IN NO EVENT SHALL
 * THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
 * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING
 * FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER
 * DEALINGS IN THE SOFTWARE.
 ****************************************************************************/

#include "cpl_port.h"
#include "gdal.h"
#include "gdal_priv.h"

#include <cstddef>
#include <cstring>

#include <algorithm>

#include "cpl_conv.h"
#include "cpl_error.h"
#include "cpl_virtualmem.h"

// To be changed if we go to 64-bit RasterIO coordinates and spacing.
using coord_type = int;
using spacing_type = int;

/************************************************************************/
/*                            GDALVirtualMem                            */
/************************************************************************/

class GDALVirtualMem
{
    GDALDatasetH hDS = nullptr;
    GDALRasterBandH hBand = nullptr;
    coord_type nXOff = 0;
    coord_type nYOff = 0;
    // int nXSize;
    // int nYSize;
    coord_type nBufXSize = 0;
    coord_type nBufYSize = 0;
    GDALDataType eBufType = GDT_Byte;
    int nBandCount = 0;
    int *panBandMap = nullptr;
    int nPixelSpace = 0;
    GIntBig nLineSpace = 0;
    GIntBig nBandSpace = 0;

    bool bIsCompact = false;
    bool bIsBandSequential = false;

    bool IsCompact() const
    {
        return bIsCompact;
    }
    bool IsBandSequential() const
    {
        return bIsBandSequential;
    }

    void GetXYBand(size_t nOffset, coord_type &x, coord_type &y,
                   int &band) const;
    size_t GetOffset(const coord_type &x, const coord_type &y, int band) const;
    bool GotoNextPixel(coord_type &x, coord_type &y, int &band) const;

    void DoIOBandSequential(GDALRWFlag eRWFlag, size_t nOffset, void *pPage,
                            size_t nBytes) const;
    void DoIOPixelInterleaved(GDALRWFlag eRWFlag, size_t nOffset, void *pPage,
                              size_t nBytes) const;

    CPL_DISALLOW_COPY_ASSIGN(GDALVirtualMem)

  public:
    GDALVirtualMem(GDALDatasetH hDS, GDALRasterBandH hBand,
                   const coord_type &nXOff, const coord_type &nYOff,
                   const coord_type &nXSize, const coord_type &nYSize,
                   const coord_type &nBufXSize, const coord_type &nBufYSize,
                   GDALDataType eBufType, int nBandCount,
                   const int *panBandMapIn, int nPixelSpace, GIntBig nLineSpace,
                   GIntBig nBandSpace);
    ~GDALVirtualMem();

    static void FillCacheBandSequential(CPLVirtualMem *ctxt, size_t nOffset,
                                        void *pPageToFill, size_t nToFill,
                                        void *pUserData);
    static void SaveFromCacheBandSequential(CPLVirtualMem *ctxt, size_t nOffset,
                                            const void *pPageToBeEvicted,
                                            size_t nToEvicted, void *pUserData);

    static void FillCachePixelInterleaved(CPLVirtualMem *ctxt, size_t nOffset,
                                          void *pPageToFill, size_t nToFill,
                                          void *pUserData);
    static void SaveFromCachePixelInterleaved(CPLVirtualMem *ctxt,
                                              size_t nOffset,
                                              const void *pPageToBeEvicted,
                                              size_t nToEvicted,
                                              void *pUserData);

    static void Destroy(void *pUserData);
};

/************************************************************************/
/*                             GDALVirtualMem()                         */
/************************************************************************/

GDALVirtualMem::GDALVirtualMem(
    GDALDatasetH hDSIn, GDALRasterBandH hBandIn, const coord_type &nXOffIn,
    const coord_type &nYOffIn, const coord_type & /* nXSize */,
    const coord_type & /* nYSize */, const coord_type &nBufXSizeIn,
    const coord_type &nBufYSizeIn, GDALDataType eBufTypeIn, int nBandCountIn,
    const int *panBandMapIn, int nPixelSpaceIn, GIntBig nLineSpaceIn,
    GIntBig nBandSpaceIn)
    : hDS(hDSIn), hBand(hBandIn), nXOff(nXOffIn), nYOff(nYOffIn),
      // TODO(schwehr): Why not used or removed?
      // nXSize(nXSize),
      // nYSize(nYSize),
      nBufXSize(nBufXSizeIn), nBufYSize(nBufYSizeIn), eBufType(eBufTypeIn),
      nBandCount(nBandCountIn), nPixelSpace(nPixelSpaceIn),
      nLineSpace(nLineSpaceIn), nBandSpace(nBandSpaceIn)
{
    if (hDS != nullptr)
    {
        panBandMap = static_cast<int *>(CPLMalloc(nBandCount * sizeof(int)));
        if (panBandMapIn)
        {
            memcpy(panBandMap, panBandMapIn, nBandCount * sizeof(int));
        }
        else
        {
            for (int i = 0; i < nBandCount; i++)
                panBandMap[i] = i + 1;
        }
    }
    else
    {
        panBandMap = nullptr;
        nBandCount = 1;
    }

    const int nDataTypeSize = GDALGetDataTypeSizeBytes(eBufType);
    if (nPixelSpace == nDataTypeSize &&
        nLineSpace == static_cast<GIntBig>(nBufXSize) * nPixelSpace &&
        nBandSpace == nBufYSize * nLineSpace)
        bIsCompact = true;
    else if (nBandSpace == nDataTypeSize &&
             nPixelSpace == nBandCount * nBandSpace &&
             nLineSpace == static_cast<GIntBig>(nBufXSize) * nPixelSpace)
        bIsCompact = true;
    else
        bIsCompact = false;

    bIsBandSequential = nBandSpace >= nBufYSize * nLineSpace;
}

/************************************************************************/
/*                            ~GDALVirtualMem()                         */
/************************************************************************/

GDALVirtualMem::~GDALVirtualMem()
{
    CPLFree(panBandMap);
}

/************************************************************************/
/*                              GetXYBand()                             */
/************************************************************************/

void GDALVirtualMem::GetXYBand(size_t nOffset, coord_type &x, coord_type &y,
                               int &band) const
{
    if (IsBandSequential())
    {
        if (nBandCount == 1)
            band = 0;
        else
            band = static_cast<int>(nOffset / nBandSpace);
        y = static_cast<coord_type>((nOffset - band * nBandSpace) / nLineSpace);
        x = static_cast<coord_type>(
            (nOffset - band * nBandSpace - y * nLineSpace) / nPixelSpace);
    }
    else
    {
        y = static_cast<coord_type>(nOffset / nLineSpace);
        x = static_cast<coord_type>((nOffset - y * nLineSpace) / nPixelSpace);
        if (nBandCount == 1)
            band = 0;
        else
            band = static_cast<int>((nOffset - y * nLineSpace -
                                     static_cast<size_t>(x) * nPixelSpace) /
                                    nBandSpace);
    }
}

/************************************************************************/
/*                            GotoNextPixel()                           */
/************************************************************************/

bool GDALVirtualMem::GotoNextPixel(coord_type &x, coord_type &y,
                                   int &band) const
{
    if (IsBandSequential())
    {
        ++x;
        if (x == nBufXSize)
        {
            x = 0;
            ++y;
        }
        if (y == nBufYSize)
        {
            y = 0;
            band++;
            if (band == nBandCount)
                return false;
        }
    }
    else
    {
        band++;
        if (band == nBandCount)
        {
            band = 0;
            ++x;
        }
        if (x == nBufXSize)
        {
            x = 0;
            ++y;
            if (y == nBufYSize)
                return false;
        }
    }
    return true;
}

/************************************************************************/
/*                              GetOffset()                             */
/************************************************************************/

size_t GDALVirtualMem::GetOffset(const coord_type &x, const coord_type &y,
                                 int band) const
{
    return static_cast<size_t>(static_cast<size_t>(x) * nPixelSpace +
                               y * nLineSpace + band * nBandSpace);
}

/************************************************************************/
/*                          DoIOPixelInterleaved()                      */
/************************************************************************/

void GDALVirtualMem::DoIOPixelInterleaved(GDALRWFlag eRWFlag,
                                          const size_t nOffset, void *pPage,
                                          size_t nBytes) const
{
    coord_type x = 0;
    coord_type y = 0;
    int band = 0;

    GetXYBand(nOffset, x, y, band);
#ifdef DEBUG_VERBOSE
    fprintf(stderr, "eRWFlag=%d, nOffset=%d, x=%d, y=%d, band=%d\n", /*ok*/
            eRWFlag, static_cast<int>(nOffset), x, y, band);
#endif

    if (eRWFlag == GF_Read && !IsCompact())
        memset(pPage, 0, nBytes);

    if (band >= nBandCount)
    {
        band = nBandCount - 1;
        if (!GotoNextPixel(x, y, band))
            return;
    }
    else if (x >= nBufXSize)
    {
        x = nBufXSize - 1;
        band = nBandCount - 1;
        if (!GotoNextPixel(x, y, band))
            return;
    }

    size_t nOffsetRecompute = GetOffset(x, y, band);
    CPLAssert(nOffsetRecompute >= nOffset);
    size_t nOffsetShift = nOffsetRecompute - nOffset;
    if (nOffsetShift >= nBytes)
        return;

    // If we don't start at the first band for that given pixel, load/store
    // the remaining bands
    if (band > 0)
    {
        size_t nEndOffsetEndOfPixel = GetOffset(x, y, nBandCount);
        int bandEnd = nBandCount;
        // Check that we have enough space to load/store until last band
        // Should be always OK unless the number of bands is really huge
        if (nEndOffsetEndOfPixel - nOffset > nBytes)
        {
            // Not enough space: find last possible band
            coord_type xEnd, yEnd;
            GetXYBand(nOffset + nBytes, xEnd, yEnd, bandEnd);
            CPLAssert(x == xEnd);
            CPLAssert(y == yEnd);
        }

        // Finish reading/writing the remaining bands for that pixel
        CPL_IGNORE_RET_VAL(GDALDatasetRasterIO(
            hDS, eRWFlag, nXOff + x, nYOff + y, 1, 1,
            static_cast<char *>(pPage) + nOffsetShift, 1, 1, eBufType,
            bandEnd - band, panBandMap + band, nPixelSpace,
            static_cast<spacing_type>(nLineSpace),
            static_cast<spacing_type>(nBandSpace)));

        if (bandEnd < nBandCount)
            return;

        band = nBandCount - 1;
        if (!GotoNextPixel(x, y, band))
            return;
        nOffsetRecompute = GetOffset(x, y, 0);
        nOffsetShift = nOffsetRecompute - nOffset;
        if (nOffsetShift >= nBytes)
            return;
    }

    // Is there enough place to store/load up to the end of current line ?
    size_t nEndOffsetEndOfLine = GetOffset(nBufXSize - 1, y, nBandCount);
    if (nEndOffsetEndOfLine - nOffset > nBytes)
    {
        // No : read/write as many pixels on this line as possible
        coord_type xEnd, yEnd;
        int bandEnd;
        GetXYBand(nOffset + nBytes, xEnd, yEnd, bandEnd);
        CPLAssert(y == yEnd);

        if (x < xEnd)
        {
            CPL_IGNORE_RET_VAL(GDALDatasetRasterIO(
                hDS, eRWFlag, nXOff + x, nYOff + y, xEnd - x, 1,
                static_cast<char *>(pPage) + nOffsetShift, xEnd - x, 1,
                eBufType, nBandCount, panBandMap, nPixelSpace,
                static_cast<spacing_type>(nLineSpace),
                static_cast<spacing_type>(nBandSpace)));
        }

        // Are there partial bands to read/write for the last pixel ?
        if (bandEnd > 0)
        {
            x = xEnd;
            nOffsetRecompute = GetOffset(x, y, 0);
            nOffsetShift = nOffsetRecompute - nOffset;
            if (nOffsetShift >= nBytes)
                return;

            if (bandEnd >= nBandCount)
                bandEnd = nBandCount;

            CPL_IGNORE_RET_VAL(GDALDatasetRasterIO(
                hDS, eRWFlag, nXOff + x, nYOff + y, 1, 1,
                static_cast<char *>(pPage) + nOffsetShift, 1, 1, eBufType,
                bandEnd, panBandMap, nPixelSpace,
                static_cast<spacing_type>(nLineSpace),
                static_cast<spacing_type>(nBandSpace)));
        }

        return;
    }

    // Yes, enough place to read/write until end of line
    if (x > 0 || nBytes - nOffsetShift < static_cast<size_t>(nLineSpace))
    {
        CPL_IGNORE_RET_VAL(GDALDatasetRasterIO(
            hDS, eRWFlag, nXOff + x, nYOff + y, nBufXSize - x, 1,
            static_cast<char *>(pPage) + nOffsetShift, nBufXSize - x, 1,
            eBufType, nBandCount, panBandMap, nPixelSpace,
            static_cast<spacing_type>(nLineSpace),
            static_cast<spacing_type>(nBandSpace)));

        // Go to beginning of next line
        x = nBufXSize - 1;
        band = nBandCount - 1;
        if (!GotoNextPixel(x, y, band))
            return;
        nOffsetRecompute = GetOffset(x, y, 0);
        nOffsetShift = nOffsetRecompute - nOffset;
        if (nOffsetShift >= nBytes)
            return;
    }

    // How many whole lines can we store/load ?
    coord_type nLineCount =
        static_cast<coord_type>((nBytes - nOffsetShift) / nLineSpace);
    if (y + nLineCount > nBufYSize)
        nLineCount = nBufYSize - y;
    if (nLineCount > 0)
    {
        CPL_IGNORE_RET_VAL(GDALDatasetRasterIO(
            hDS, eRWFlag, nXOff + 0, nYOff + y, nBufXSize, nLineCount,
            static_cast<GByte *>(pPage) + nOffsetShift, nBufXSize, nLineCount,
            eBufType, nBandCount, panBandMap, nPixelSpace,
            static_cast<spacing_type>(nLineSpace),
            static_cast<spacing_type>(nBandSpace)));

        y += nLineCount;
        if (y == nBufYSize)
            return;
        nOffsetRecompute = GetOffset(x, y, 0);
        nOffsetShift = nOffsetRecompute - nOffset;
    }

    if (nOffsetShift < nBytes)
    {
        DoIOPixelInterleaved(eRWFlag, nOffsetRecompute,
                             static_cast<char *>(pPage) + nOffsetShift,
                             nBytes - nOffsetShift);
    }
}

/************************************************************************/
/*                          DoIOPixelInterleaved()                      */
/************************************************************************/

void GDALVirtualMem::DoIOBandSequential(GDALRWFlag eRWFlag,
                                        const size_t nOffset, void *pPage,
                                        size_t nBytes) const
{
    coord_type x = 0;
    coord_type y = 0;

    int band = 0;
    GetXYBand(nOffset, x, y, band);
#if DEBUG_VERBOSE
    fprintf(stderr, "eRWFlag=%d, nOffset=%d, x=%d, y=%d, band=%d\n", /*ok*/
            eRWFlag, static_cast<int>(nOffset), x, y, band);
#endif

    if (eRWFlag == GF_Read && !IsCompact())
        memset(pPage, 0, nBytes);

    if (x >= nBufXSize)
    {
        x = nBufXSize - 1;
        if (!GotoNextPixel(x, y, band))
            return;
    }
    else if (y >= nBufYSize)
    {
        x = nBufXSize - 1;
        y = nBufYSize - 1;
        if (!GotoNextPixel(x, y, band))
            return;
    }

    size_t nOffsetRecompute = GetOffset(x, y, band);
    CPLAssert(nOffsetRecompute >= nOffset);
    size_t nOffsetShift = nOffsetRecompute - nOffset;
    if (nOffsetShift >= nBytes)
        return;

    // Is there enough place to store/load up to the end of current line?
    size_t nEndOffsetEndOfLine = GetOffset(nBufXSize, y, band);
    if (nEndOffsetEndOfLine - nOffset > nBytes)
    {
        // No : read/write as many pixels on this line as possible
        coord_type xEnd, yEnd;
        int bandEnd;
        GetXYBand(nOffset + nBytes, xEnd, yEnd, bandEnd);
        CPLAssert(y == yEnd);
        CPLAssert(band == bandEnd);
        CPL_IGNORE_RET_VAL(GDALRasterIO(
            hBand ? hBand : GDALGetRasterBand(hDS, panBandMap[band]), eRWFlag,
            nXOff + x, nYOff + y, xEnd - x, 1,
            static_cast<char *>(pPage) + nOffsetShift, xEnd - x, 1, eBufType,
            nPixelSpace, static_cast<spacing_type>(nLineSpace)));

        return;
    }

    // Yes, enough place to read/write until end of line
    if (x > 0 || nBytes - nOffsetShift < static_cast<size_t>(nLineSpace))
    {
        CPL_IGNORE_RET_VAL(GDALRasterIO(
            hBand ? hBand : GDALGetRasterBand(hDS, panBandMap[band]), eRWFlag,
            nXOff + x, nYOff + y, nBufXSize - x, 1,
            static_cast<char *>(pPage) + nOffsetShift, nBufXSize - x, 1,
            eBufType, nPixelSpace, static_cast<spacing_type>(nLineSpace)));

        // Go to beginning of next line
        x = nBufXSize - 1;
        if (!GotoNextPixel(x, y, band))
            return;
        nOffsetRecompute = GetOffset(x, y, band);
        nOffsetShift = nOffsetRecompute - nOffset;
        if (nOffsetShift >= nBytes)
            return;
    }

    // How many whole lines can we store/load ?
    coord_type nLineCount =
        static_cast<coord_type>((nBytes - nOffsetShift) / nLineSpace);
    if (y + nLineCount > nBufYSize)
        nLineCount = nBufYSize - y;
    if (nLineCount > 0)
    {
        CPL_IGNORE_RET_VAL(GDALRasterIO(
            hBand ? hBand : GDALGetRasterBand(hDS, panBandMap[band]), eRWFlag,
            nXOff + 0, nYOff + y, nBufXSize, nLineCount,
            static_cast<GByte *>(pPage) + nOffsetShift, nBufXSize, nLineCount,
            eBufType, nPixelSpace, static_cast<spacing_type>(nLineSpace)));

        y += nLineCount;
        if (y == nBufYSize)
        {
            y = 0;
            band++;
            if (band == nBandCount)
                return;
        }
        nOffsetRecompute = GetOffset(x, y, band);
        nOffsetShift = nOffsetRecompute - nOffset;
    }

    if (nOffsetShift < nBytes)
    {
        DoIOBandSequential(eRWFlag, nOffsetRecompute,
                           static_cast<char *>(pPage) + nOffsetShift,
                           nBytes - nOffsetShift);
    }
}

/************************************************************************/
/*                    FillCacheBandSequential()                        */
/************************************************************************/

void GDALVirtualMem::FillCacheBandSequential(CPLVirtualMem *, size_t nOffset,
                                             void *pPageToFill, size_t nToFill,
                                             void *pUserData)
{
    const GDALVirtualMem *psParams = static_cast<GDALVirtualMem *>(pUserData);
    psParams->DoIOBandSequential(GF_Read, nOffset, pPageToFill, nToFill);
}

/************************************************************************/
/*                    SaveFromCacheBandSequential()                    */
/************************************************************************/

void GDALVirtualMem::SaveFromCacheBandSequential(CPLVirtualMem *,
                                                 size_t nOffset,
                                                 const void *pPageToBeEvicted,
                                                 size_t nToEvicted,
                                                 void *pUserData)
{
    const GDALVirtualMem *psParams = static_cast<GDALVirtualMem *>(pUserData);
    psParams->DoIOBandSequential(
        GF_Write, nOffset, const_cast<void *>(pPageToBeEvicted), nToEvicted);
}

/************************************************************************/
/*                     FillCachePixelInterleaved()                      */
/************************************************************************/

void GDALVirtualMem::FillCachePixelInterleaved(CPLVirtualMem *, size_t nOffset,
                                               void *pPageToFill,
                                               size_t nToFill, void *pUserData)
{
    const GDALVirtualMem *psParams = static_cast<GDALVirtualMem *>(pUserData);
    psParams->DoIOPixelInterleaved(GF_Read, nOffset, pPageToFill, nToFill);
}

/************************************************************************/
/*                     SaveFromCachePixelInterleaved()                  */
/************************************************************************/

void GDALVirtualMem::SaveFromCachePixelInterleaved(CPLVirtualMem *,
                                                   size_t nOffset,
                                                   const void *pPageToBeEvicted,
                                                   size_t nToEvicted,
                                                   void *pUserData)
{
    const GDALVirtualMem *psParams = static_cast<GDALVirtualMem *>(pUserData);
    psParams->DoIOPixelInterleaved(
        GF_Write, nOffset, const_cast<void *>(pPageToBeEvicted), nToEvicted);
}

/************************************************************************/
/*                                Destroy()                             */
/************************************************************************/

void GDALVirtualMem::Destroy(void *pUserData)
{
    GDALVirtualMem *psParams = static_cast<GDALVirtualMem *>(pUserData);
    delete psParams;
}

/************************************************************************/
/*                      GDALCheckBandParameters()                       */
/************************************************************************/

static bool GDALCheckBandParameters(GDALDatasetH hDS, int nBandCount,
                                    int *panBandMap)
{
    if (nBandCount == 0)
    {
        CPLError(CE_Failure, CPLE_AppDefined, "nBandCount == 0");
        return false;
    }

    if (panBandMap != nullptr)
    {
        for (int i = 0; i < nBandCount; i++)
        {
            if (panBandMap[i] < 1 || panBandMap[i] > GDALGetRasterCount(hDS))
            {
                CPLError(CE_Failure, CPLE_AppDefined, "panBandMap[%d]=%d", i,
                         panBandMap[i]);
                return false;
            }
        }
    }
    else if (nBandCount > GDALGetRasterCount(hDS))
    {
        CPLError(CE_Failure, CPLE_AppDefined,
                 "nBandCount > GDALGetRasterCount(hDS)");
        return false;
    }
    return true;
}

/************************************************************************/
/*                          GDALGetVirtualMem()                         */
/************************************************************************/

static CPLVirtualMem *
GDALGetVirtualMem(GDALDatasetH hDS, GDALRasterBandH hBand, GDALRWFlag eRWFlag,
                  coord_type nXOff, coord_type nYOff, coord_type nXSize,
                  coord_type nYSize, coord_type nBufXSize, coord_type nBufYSize,
                  GDALDataType eBufType, int nBandCount, int *panBandMap,
                  int nPixelSpace, GIntBig nLineSpace, GIntBig nBandSpace,
                  size_t nCacheSize, size_t nPageSizeHint,
                  int bSingleThreadUsage, CSLConstList /*papszOptions*/)
{
    CPLVirtualMem *view = nullptr;
    GDALVirtualMem *psParams = nullptr;
    GUIntBig nReqMem = 0;

    if (nXSize != nBufXSize || nYSize != nBufYSize)
    {
        CPLError(CE_Failure, CPLE_NotSupported,
                 "nXSize != nBufXSize || nYSize != nBufYSize");
        return nullptr;
    }

    int nRasterXSize =
        hDS ? GDALGetRasterXSize(hDS) : GDALGetRasterBandXSize(hBand);
    int nRasterYSize =
        hDS ? GDALGetRasterYSize(hDS) : GDALGetRasterBandYSize(hBand);

    if (nXOff < 0 || nYOff < 0 || nXSize == 0 || nYSize == 0 || nBufXSize < 0 ||
        nBufYSize < 0 || nXOff + nXSize > nRasterXSize ||
        nYOff + nYSize > nRasterYSize)
    {
        CPLError(CE_Failure, CPLE_AppDefined, "Invalid window request");
        return nullptr;
    }

    if (nPixelSpace < 0 || nLineSpace < 0 || nBandSpace < 0)
    {
        CPLError(CE_Failure, CPLE_NotSupported,
                 "nPixelSpace < 0 || nLineSpace < 0 || nBandSpace < 0");
        return nullptr;
    }

    if (hDS != nullptr && !GDALCheckBandParameters(hDS, nBandCount, panBandMap))
        return nullptr;

    const int nDataTypeSize = GDALGetDataTypeSizeBytes(eBufType);
    if (nPixelSpace == 0)
        nPixelSpace = nDataTypeSize;
    if (nLineSpace == 0)
        nLineSpace = static_cast<GIntBig>(nBufXSize) * nPixelSpace;
    if (nBandSpace == 0)
        nBandSpace = static_cast<GIntBig>(nBufYSize) * nLineSpace;

    // OFFSET = offset(x,y,band) = x * nPixelSpace + y * nLineSpace + band *
    // nBandSpace where 0 <= x < nBufXSize and 0 <= y < nBufYSize and 0 <= band
    // < nBandCount if nPixelSpace, nLineSpace and nBandSpace can have arbitrary
    // values, there is no way of finding a unique(x,y,band) solution. We need
    // to restrict the space of possibilities strongly.
    // if nBandSpace >= nBufYSize * nLineSpace and
    //   nLineSpace >= nBufXSize * nPixelSpace,           INTERLEAVE = BAND
    //      band = OFFSET / nBandSpace
    //      y = (OFFSET - band * nBandSpace) / nLineSpace
    //      x = (OFFSET - band * nBandSpace - y * nLineSpace) / nPixelSpace
    // else if nPixelSpace >= nBandCount * nBandSpace and
    //   nLineSpace >= nBufXSize * nPixelSpace,    INTERLEAVE = PIXEL
    //      y = OFFSET / nLineSpace
    //      x = (OFFSET - y * nLineSpace) / nPixelSpace
    //      band = (OFFSET - y * nLineSpace - x * nPixelSpace) / nBandSpace

    if (nDataTypeSize == 0 || /* to please Coverity. not needed */
        nLineSpace < static_cast<GIntBig>(nBufXSize) * nPixelSpace ||
        (nBandCount > 1 &&
         (nBandSpace == nPixelSpace ||
          (nBandSpace < nPixelSpace &&
           (nBandSpace < nDataTypeSize ||
            nPixelSpace < nBandCount * nBandSpace)) ||
          (nBandSpace > nPixelSpace && (nPixelSpace < nDataTypeSize ||
                                        nBandSpace < nBufYSize * nLineSpace)))))
    {
        CPLError(CE_Failure, CPLE_NotSupported,
                 "Only pixel interleaving or band interleaving are supported");
        return nullptr;
    }

    /* Avoid odd spacings that would complicate I/O operations */
    /* Ensuring they are multiple of nDataTypeSize should be fine, because */
    /* the page size is a power of 2 that is also a multiple of nDataTypeSize */
    if ((nPixelSpace % nDataTypeSize) != 0 ||
        (nLineSpace % nDataTypeSize) != 0 || (nBandSpace % nDataTypeSize) != 0)
    {
        CPLError(CE_Failure, CPLE_NotSupported, "Unsupported spacing");
        return nullptr;
    }

    bool bIsBandSequential = nBandSpace >= nBufYSize * nLineSpace;
    if (bIsBandSequential)
        nReqMem = nBandCount * nBandSpace;
    else
        nReqMem = nBufYSize * nLineSpace;
    if (nReqMem != static_cast<GUIntBig>(static_cast<size_t>(nReqMem)))
    {
        CPLError(CE_Failure, CPLE_OutOfMemory,
                 "Cannot reserve " CPL_FRMT_GUIB " bytes", nReqMem);
        return nullptr;
    }

    psParams = new GDALVirtualMem(
        hDS, hBand, nXOff, nYOff, nXSize, nYSize, nBufXSize, nBufYSize,
        eBufType, nBandCount, panBandMap, nPixelSpace, nLineSpace, nBandSpace);

    view = CPLVirtualMemNew(
        static_cast<size_t>(nReqMem), nCacheSize, nPageSizeHint,
        bSingleThreadUsage,
        eRWFlag == GF_Read ? VIRTUALMEM_READONLY_ENFORCED
                           : VIRTUALMEM_READWRITE,
        bIsBandSequential ? GDALVirtualMem::FillCacheBandSequential
                          : GDALVirtualMem::FillCachePixelInterleaved,
        bIsBandSequential ? GDALVirtualMem::SaveFromCacheBandSequential
                          : GDALVirtualMem::SaveFromCachePixelInterleaved,
        GDALVirtualMem::Destroy, psParams);

    if (view == nullptr)
    {
        delete psParams;
    }

    return view;
}

/************************************************************************/
/*                       GDALDatasetGetVirtualMem()                     */
/************************************************************************/

/** Create a CPLVirtualMem object from a GDAL dataset object.
 *
 * Only supported on Linux for now.
 *
 * This method allows creating a virtual memory object for a region of one
 * or more GDALRasterBands from  this dataset. The content of the virtual
 * memory object is automatically filled from dataset content when a virtual
 * memory page is first accessed, and it is released (or flushed in case of a
 * "dirty" page) when the cache size limit has been reached.
 *
 * The pointer to access the virtual memory object is obtained with
 * CPLVirtualMemGetAddr(). It remains valid until CPLVirtualMemFree() is called.
 * CPLVirtualMemFree() must be called before the dataset object is destroyed.
 *
 * If p is such a pointer and base_type the C type matching eBufType, for
 * default values of spacing parameters, the element of image coordinates (x, y)
 * (relative to xOff, yOff) for band b can be accessed with
 * ((base_type*)p)[x + y * nBufXSize + (b-1)*nBufXSize*nBufYSize].
 *
 * Note that the mechanism used to transparently fill memory pages when they are
 * accessed is the same (but in a controlled way) than what occurs when a memory
 * error occurs in a program. Debugging software will generally interrupt
 * program execution when that happens. If needed, CPLVirtualMemPin() can be
 * used to avoid that by ensuring memory pages are allocated before being
 * accessed.
 *
 * The size of the region that can be mapped as a virtual memory object depends
 * on hardware and operating system limitations.
 * On Linux AMD64 platforms, the maximum value is 128 TB.
 * On Linux x86 platforms, the maximum value is 2 GB.
 *
 * Data type translation is automatically done if the data type
 * (eBufType) of the buffer is different than
 * that of the GDALRasterBand.
 *
 * Image decimation / replication is currently not supported, i.e. if the
 * size of the region being accessed (nXSize x nYSize) is different from the
 * buffer size (nBufXSize x nBufYSize).
 *
 * The nPixelSpace, nLineSpace and nBandSpace parameters allow reading into or
 * writing from various organization of buffers. Arbitrary values for the
 * spacing parameters are not supported. Those values must be multiple of the
 * size of thebuffer data type, and must be either band sequential
 * organization (typically nPixelSpace = GDALGetDataTypeSizeBytes(eBufType),
 * nLineSpace = nPixelSpace * nBufXSize,
 * nBandSpace = nLineSpace * nBufYSize), or pixel-interleaved organization
 * (typically nPixelSpace = nBandSpace * nBandCount,
 * nLineSpace = nPixelSpace * nBufXSize,
 * nBandSpace = GDALGetDataTypeSizeBytes(eBufType))
 *
 * @param hDS Dataset object
 *
 * @param eRWFlag Either GF_Read to read a region of data, or GF_Write to
 * write a region of data.
 *
 * @param nXOff The pixel offset to the top left corner of the region
 * of the band to be accessed.  This would be zero to start from the left side.
 *
 * @param nYOff The line offset to the top left corner of the region
 * of the band to be accessed.  This would be zero to start from the top.
 *
 * @param nXSize The width of the region of the band to be accessed in pixels.
 *
 * @param nYSize The height of the region of the band to be accessed in lines.
 *
 * @param nBufXSize the width of the buffer image into which the desired region
 * is to be read, or from which it is to be written.
 *
 * @param nBufYSize the height of the buffer image into which the desired
 * region is to be read, or from which it is to be written.
 *
 * @param eBufType the type of the pixel values in the data buffer. The
 * pixel values will automatically be translated to/from the GDALRasterBand
 * data type as needed.
 *
 * @param nBandCount the number of bands being read or written.
 *
 * @param panBandMap the list of nBandCount band numbers being read/written.
 * Note band numbers are 1 based. This may be NULL to select the first
 * nBandCount bands.
 *
 * @param nPixelSpace The byte offset from the start of one pixel value in
 * the buffer to the start of the next pixel value within a scanline. If
 * defaulted (0) the size of the datatype eBufType is used.
 *
 * @param nLineSpace The byte offset from the start of one scanline in
 * the buffer to the start of the next. If defaulted (0) the size of the
 * datatype eBufType * nBufXSize is used.
 *
 * @param nBandSpace the byte offset from the start of one bands data to the
 * start of the next. If defaulted (0) the value will be
 * nLineSpace * nBufYSize implying band sequential organization
 * of the data buffer.
 *
 * @param nCacheSize   size in bytes of the maximum memory that will be really
 *                     allocated (must ideally fit into RAM)
 *
 * @param nPageSizeHint hint for the page size. Must be a multiple of the
 *                      system page size, returned by CPLGetPageSize().
 *                      Minimum value is generally 4096. Might be set to 0 to
 *                      let the function determine a default page size.
 *
 * @param bSingleThreadUsage set to TRUE if there will be no concurrent threads
 *                           that will access the virtual memory mapping. This
 *                           can optimize performance a bit. If set to FALSE,
 *                           CPLVirtualMemDeclareThread() must be called.
 *
 * @param papszOptions NULL terminated list of options. Unused for now.
 *
 * @return a virtual memory object that must be freed by CPLVirtualMemFree(),
 *         or NULL in case of failure.
 *
 * @since GDAL 1.11
 */

CPLVirtualMem *GDALDatasetGetVirtualMem(
    GDALDatasetH hDS, GDALRWFlag eRWFlag, int nXOff, int nYOff, int nXSize,
    int nYSize, int nBufXSize, int nBufYSize, GDALDataType eBufType,
    int nBandCount, int *panBandMap, int nPixelSpace, GIntBig nLineSpace,
    GIntBig nBandSpace, size_t nCacheSize, size_t nPageSizeHint,
    int bSingleThreadUsage, CSLConstList papszOptions)
{
    return GDALGetVirtualMem(hDS, nullptr, eRWFlag, nXOff, nYOff, nXSize,
                             nYSize, nBufXSize, nBufYSize, eBufType, nBandCount,
                             panBandMap, nPixelSpace, nLineSpace, nBandSpace,
                             nCacheSize, nPageSizeHint, bSingleThreadUsage,
                             papszOptions);
}

/************************************************************************/
/*                     GDALRasterBandGetVirtualMem()                    */
/************************************************************************/

/** Create a CPLVirtualMem object from a GDAL raster band object.
 *
 * Only supported on Linux for now.
 *
 * This method allows creating a virtual memory object for a region of a
 * GDALRasterBand. The content of the virtual
 * memory object is automatically filled from dataset content when a virtual
 * memory page is first accessed, and it is released (or flushed in case of a
 * "dirty" page) when the cache size limit has been reached.
 *
 * The pointer to access the virtual memory object is obtained with
 * CPLVirtualMemGetAddr(). It remains valid until CPLVirtualMemFree() is called.
 * CPLVirtualMemFree() must be called before the raster band object is
 * destroyed.
 *
 * If p is such a pointer and base_type the C type matching eBufType, for
 * values of spacing parameters, the element of image coordinates (x, y)
 * default (relative to xOff, yOff) can be accessed with
 * ((base_type*)p)[x + y * nBufXSize].
 *
 * Note that the mechanism used to transparently fill memory pages when they are
 * accessed is the same (but in a controlled way) than what occurs when a memory
 * error occurs in a program. Debugging software will generally interrupt
 * program execution when that happens. If needed, CPLVirtualMemPin() can be
 * used to avoid that by ensuring memory pages are allocated before being
 * accessed.
 *
 * The size of the region that can be mapped as a virtual memory object depends
 * on hardware and operating system limitations.
 * On Linux AMD64 platforms, the maximum value is 128 TB.
 * On Linux x86 platforms, the maximum value is 2 GB.
 *
 * Data type translation is automatically done if the data type
 * (eBufType) of the buffer is different than
 * that of the GDALRasterBand.
 *
 * Image decimation / replication is currently not supported, i.e. if the
 * size of the region being accessed (nXSize x nYSize) is different from the
 * buffer size (nBufXSize x nBufYSize).
 *
 * The nPixelSpace and nLineSpace parameters allow reading into or
 * writing from various organization of buffers. Arbitrary values for the
 * spacing parameters are not supported. Those values must be multiple of the
 * size of the buffer data type and must be such that nLineSpace >=
 * nPixelSpace * nBufXSize.
 *
 * @param hBand Rasterband object
 *
 * @param eRWFlag Either GF_Read to read a region of data, or GF_Write to
 * write a region of data.
 *
 * @param nXOff The pixel offset to the top left corner of the region
 * of the band to be accessed.  This would be zero to start from the left side.
 *
 * @param nYOff The line offset to the top left corner of the region
 * of the band to be accessed.  This would be zero to start from the top.
 *
 * @param nXSize The width of the region of the band to be accessed in pixels.
 *
 * @param nYSize The height of the region of the band to be accessed in lines.
 *
 * @param nBufXSize the width of the buffer image into which the desired region
 * is to be read, or from which it is to be written.
 *
 * @param nBufYSize the height of the buffer image into which the desired
 * region is to be read, or from which it is to be written.
 *
 * @param eBufType the type of the pixel values in the data buffer. The
 * pixel values will automatically be translated to/from the GDALRasterBand
 * data type as needed.
 *
 * @param nPixelSpace The byte offset from the start of one pixel value in the
 * buffer to the start of the next pixel value within a scanline. If defaulted
 * (0) the size of the datatype eBufType is used.
 *
 * @param nLineSpace The byte offset from the start of one scanline in the
 * buffer to the start of the next. If defaulted (0) the size of the datatype
 * eBufType * nBufXSize is used.
 *
 * @param nCacheSize   size in bytes of the maximum memory that will be really
 *                     allocated (must ideally fit into RAM)
 *
 * @param nPageSizeHint hint for the page size. Must be a multiple of the
 *                      system page size, returned by CPLGetPageSize().
 *                      Minimum value is generally 4096. Might be set to 0 to
 *                      let the function determine a default page size.
 *
 * @param bSingleThreadUsage set to TRUE if there will be no concurrent threads
 *                           that will access the virtual memory mapping. This
 *                           can optimize performance a bit. If set to FALSE,
 *                           CPLVirtualMemDeclareThread() must be called.
 *
 * @param papszOptions NULL terminated list of options. Unused for now.
 *
 * @return a virtual memory object that must be freed by CPLVirtualMemFree(),
 *         or NULL in case of failure.
 *
 * @since GDAL 1.11
 */

CPLVirtualMem *GDALRasterBandGetVirtualMem(
    GDALRasterBandH hBand, GDALRWFlag eRWFlag, int nXOff, int nYOff, int nXSize,
    int nYSize, int nBufXSize, int nBufYSize, GDALDataType eBufType,
    int nPixelSpace, GIntBig nLineSpace, size_t nCacheSize,
    size_t nPageSizeHint, int bSingleThreadUsage, CSLConstList papszOptions)
{
    return GDALGetVirtualMem(nullptr, hBand, eRWFlag, nXOff, nYOff, nXSize,
                             nYSize, nBufXSize, nBufYSize, eBufType, 1, nullptr,
                             nPixelSpace, nLineSpace, 0, nCacheSize,
                             nPageSizeHint, bSingleThreadUsage, papszOptions);
}

/************************************************************************/
/*                        GDALTiledVirtualMem                           */
/************************************************************************/

class GDALTiledVirtualMem
{
    GDALDatasetH hDS = nullptr;
    GDALRasterBandH hBand = nullptr;
    int nXOff = 0;
    int nYOff = 0;
    int nXSize = 0;
    int nYSize = 0;
    int nTileXSize = 0;
    int nTileYSize = 0;
    GDALDataType eBufType = GDT_Byte;
    int nBandCount = 0;
    int *panBandMap = nullptr;
    GDALTileOrganization eTileOrganization = GTO_TIP;

    void DoIO(GDALRWFlag eRWFlag, size_t nOffset, void *pPage,
              size_t nBytes) const;

    CPL_DISALLOW_COPY_ASSIGN(GDALTiledVirtualMem)

  public:
    GDALTiledVirtualMem(GDALDatasetH hDS, GDALRasterBandH hBand, int nXOff,
                        int nYOff, int nXSize, int nYSize, int nTileXSize,
                        int nTileYSize, GDALDataType eBufType, int nBandCount,
                        const int *panBandMapIn,
                        GDALTileOrganization eTileOrganization);
    ~GDALTiledVirtualMem();

    static void FillCache(CPLVirtualMem *ctxt, size_t nOffset,
                          void *pPageToFill, size_t nPageSize, void *pUserData);
    static void SaveFromCache(CPLVirtualMem *ctxt, size_t nOffset,
                              const void *pPageToBeEvicted, size_t nToEvicted,
                              void *pUserData);

    static void Destroy(void *pUserData);
};

/************************************************************************/
/*                        GDALTiledVirtualMem()                         */
/************************************************************************/

GDALTiledVirtualMem::GDALTiledVirtualMem(
    GDALDatasetH hDSIn, GDALRasterBandH hBandIn, int nXOffIn, int nYOffIn,
    int nXSizeIn, int nYSizeIn, int nTileXSizeIn, int nTileYSizeIn,
    GDALDataType eBufTypeIn, int nBandCountIn, const int *panBandMapIn,
    GDALTileOrganization eTileOrganizationIn)
    : hDS(hDSIn), hBand(hBandIn), nXOff(nXOffIn), nYOff(nYOffIn),
      nXSize(nXSizeIn), nYSize(nYSizeIn), nTileXSize(nTileXSizeIn),
      nTileYSize(nTileYSizeIn), eBufType(eBufTypeIn), nBandCount(nBandCountIn),
      eTileOrganization(eTileOrganizationIn)
{
    if (hDS != nullptr)
    {
        panBandMap = static_cast<int *>(CPLMalloc(nBandCount * sizeof(int)));
        if (panBandMapIn)
        {
            memcpy(panBandMap, panBandMapIn, nBandCount * sizeof(int));
        }
        else
        {
            for (int i = 0; i < nBandCount; i++)
                panBandMap[i] = i + 1;
        }
    }
    else
    {
        panBandMap = nullptr;
        nBandCount = 1;
    }
}

/************************************************************************/
/*                       ~GDALTiledVirtualMem()                         */
/************************************************************************/

GDALTiledVirtualMem::~GDALTiledVirtualMem()
{
    CPLFree(panBandMap);
}

/************************************************************************/
/*                                DoIO()                                */
/************************************************************************/

void GDALTiledVirtualMem::DoIO(GDALRWFlag eRWFlag, size_t nOffset, void *pPage,
                               size_t nBytes) const
{
    const int nDataTypeSize = GDALGetDataTypeSizeBytes(eBufType);
    const int nTilesPerRow = (nXSize + nTileXSize - 1) / nTileXSize;
    const int nTilesPerCol = (nYSize + nTileYSize - 1) / nTileYSize;
    size_t nPageSize =
        static_cast<size_t>(nTileXSize) * nTileYSize * nDataTypeSize;
    if (eTileOrganization != GTO_BSQ)
        nPageSize *= nBandCount;
    CPLAssert((nOffset % nPageSize) == 0);
    CPLAssert(nBytes == nPageSize);
    size_t nTile = 0;
    int band = 0;
    int nPixelSpace = 0;
    int nLineSpace = 0;
    int nBandSpace = 0;
    if (eTileOrganization == GTO_TIP)
    {
        nTile = nOffset / nPageSize;
        band = 0;
        nPixelSpace = nDataTypeSize * nBandCount;
        nLineSpace = nPixelSpace * nTileXSize;
        nBandSpace = nDataTypeSize;
    }
    else if (eTileOrganization == GTO_BIT)
    {
        nTile = nOffset / nPageSize;
        band = 0;
        nPixelSpace = nDataTypeSize;
        nLineSpace = nPixelSpace * nTileXSize;
        nBandSpace = nLineSpace * nTileYSize;
    }
    else
    {
        // offset = nPageSize * (band * nTilesPerRow * nTilesPerCol + nTile)
        band = static_cast<int>(nOffset / (static_cast<size_t>(nPageSize) *
                                           nTilesPerRow * nTilesPerCol));
        nTile = nOffset / nPageSize -
                static_cast<size_t>(band) * nTilesPerRow * nTilesPerCol;
        nPixelSpace = nDataTypeSize;
        nLineSpace = nPixelSpace * nTileXSize;
        nBandSpace = 0;
        band++;
    }
    size_t nYTile = nTile / nTilesPerRow;
    size_t nXTile = nTile - nYTile * nTilesPerRow;

    int nReqXSize =
        std::min(nTileXSize, nXSize - static_cast<int>(nXTile * nTileXSize));
    int nReqYSize =
        std::min(nTileYSize, nYSize - static_cast<int>(nYTile * nTileYSize));
    if (eRWFlag == GF_Read &&
        (nReqXSize < nTileXSize || nReqYSize < nTileYSize))
        memset(pPage, 0, nBytes);
    if (hDS != nullptr)
    {
        CPL_IGNORE_RET_VAL(GDALDatasetRasterIO(
            hDS, eRWFlag, static_cast<int>(nXOff + nXTile * nTileXSize),
            static_cast<int>(nYOff + nYTile * nTileYSize), nReqXSize, nReqYSize,
            pPage, nReqXSize, nReqYSize, eBufType,
            eTileOrganization != GTO_BSQ ? nBandCount : 1,
            eTileOrganization != GTO_BSQ ? panBandMap : &band, nPixelSpace,
            nLineSpace, nBandSpace));
    }
    else
    {
        CPL_IGNORE_RET_VAL(GDALRasterIO(
            hBand, eRWFlag, static_cast<int>(nXOff + nXTile * nTileXSize),
            static_cast<int>(nYOff + nYTile * nTileYSize), nReqXSize, nReqYSize,
            pPage, nReqXSize, nReqYSize, eBufType, nPixelSpace, nLineSpace));
    }
}

/************************************************************************/
/*                           FillCache()                                */
/************************************************************************/

void GDALTiledVirtualMem::FillCache(CPLVirtualMem *, size_t nOffset,
                                    void *pPageToFill, size_t nToFill,
                                    void *pUserData)
{
    const GDALTiledVirtualMem *psParams =
        static_cast<GDALTiledVirtualMem *>(pUserData);
    psParams->DoIO(GF_Read, nOffset, pPageToFill, nToFill);
}

/************************************************************************/
/*                          SaveFromCache()                             */
/************************************************************************/

void GDALTiledVirtualMem::SaveFromCache(CPLVirtualMem *, size_t nOffset,
                                        const void *pPageToBeEvicted,
                                        size_t nToEvicted, void *pUserData)
{
    const GDALTiledVirtualMem *psParams =
        static_cast<GDALTiledVirtualMem *>(pUserData);
    psParams->DoIO(GF_Write, nOffset, const_cast<void *>(pPageToBeEvicted),
                   nToEvicted);
}

/************************************************************************/
/*                                Destroy()                             */
/************************************************************************/

void GDALTiledVirtualMem::Destroy(void *pUserData)
{
    GDALTiledVirtualMem *psParams =
        static_cast<GDALTiledVirtualMem *>(pUserData);
    delete psParams;
}

/************************************************************************/
/*                      GDALGetTiledVirtualMem()                        */
/************************************************************************/

static CPLVirtualMem *GDALGetTiledVirtualMem(
    GDALDatasetH hDS, GDALRasterBandH hBand, GDALRWFlag eRWFlag, int nXOff,
    int nYOff, int nXSize, int nYSize, int nTileXSize, int nTileYSize,
    GDALDataType eBufType, int nBandCount, int *panBandMap,
    GDALTileOrganization eTileOrganization, size_t nCacheSize,
    int bSingleThreadUsage, CSLConstList /* papszOptions */)
{
    CPLVirtualMem *view;
    GDALTiledVirtualMem *psParams;

    size_t nPageSize = CPLGetPageSize();
    if (nPageSize == 0)
    {
        CPLError(CE_Failure, CPLE_NotSupported,
                 "GDALGetTiledVirtualMem() unsupported on this "
                 "operating system / configuration");
        return nullptr;
    }

    int nRasterXSize =
        hDS ? GDALGetRasterXSize(hDS) : GDALGetRasterBandXSize(hBand);
    int nRasterYSize =
        hDS ? GDALGetRasterYSize(hDS) : GDALGetRasterBandYSize(hBand);

    if (nXOff < 0 || nYOff < 0 || nTileXSize <= 0 || nTileYSize <= 0 ||
        nXOff + nXSize > nRasterXSize || nYOff + nYSize > nRasterYSize)
    {
        CPLError(CE_Failure, CPLE_AppDefined, "Invalid window request");
        return nullptr;
    }

    if (hDS != nullptr && !GDALCheckBandParameters(hDS, nBandCount, panBandMap))
        return nullptr;

    const int nDataTypeSize = GDALGetDataTypeSizeBytes(eBufType);
    int nTilesPerRow = (nXSize + nTileXSize - 1) / nTileXSize;
    int nTilesPerCol = (nYSize + nTileYSize - 1) / nTileYSize;
    GUIntBig nReqMem = static_cast<GUIntBig>(nTilesPerRow) * nTilesPerCol *
                       nTileXSize * nTileYSize * nBandCount * nDataTypeSize;
#if SIZEOF_SIZE_T == 4
    if (nReqMem != static_cast<GUIntBig>(static_cast<size_t>(nReqMem)))
    {
        CPLError(CE_Failure, CPLE_OutOfMemory,
                 "Cannot reserve " CPL_FRMT_GUIB " bytes", nReqMem);
        return nullptr;
    }
#endif

    size_t nPageSizeHint =
        static_cast<size_t>(nTileXSize) * nTileYSize * nDataTypeSize;
    if (eTileOrganization != GTO_BSQ)
        nPageSizeHint *= nBandCount;
    if ((nPageSizeHint % nPageSize) != 0)
    {
        CPLError(CE_Failure, CPLE_AppDefined,
                 "Tile dimensions incompatible with page size");
        return nullptr;
    }

    psParams = new GDALTiledVirtualMem(
        hDS, hBand, nXOff, nYOff, nXSize, nYSize, nTileXSize, nTileYSize,
        eBufType, nBandCount, panBandMap, eTileOrganization);

    view = CPLVirtualMemNew(static_cast<size_t>(nReqMem), nCacheSize,
                            nPageSizeHint, bSingleThreadUsage,
                            eRWFlag == GF_Read ? VIRTUALMEM_READONLY_ENFORCED
                                               : VIRTUALMEM_READWRITE,
                            GDALTiledVirtualMem::FillCache,
                            GDALTiledVirtualMem::SaveFromCache,
                            GDALTiledVirtualMem::Destroy, psParams);

    if (view == nullptr)
    {
        delete psParams;
    }
    else if (CPLVirtualMemGetPageSize(view) != nPageSizeHint)
    {
        CPLError(CE_Failure, CPLE_AppDefined,
                 "Did not get expected page size : %d vs %d",
                 static_cast<int>(CPLVirtualMemGetPageSize(view)),
                 static_cast<int>(nPageSizeHint));
        CPLVirtualMemFree(view);
        return nullptr;
    }

    return view;
}

/************************************************************************/
/*                   GDALDatasetGetTiledVirtualMem()                    */
/************************************************************************/

/** Create a CPLVirtualMem object from a GDAL dataset object, with tiling
 * organization
 *
 * Only supported on Linux for now.
 *
 * This method allows creating a virtual memory object for a region of one
 * or more GDALRasterBands from  this dataset. The content of the virtual
 * memory object is automatically filled from dataset content when a virtual
 * memory page is first accessed, and it is released (or flushed in case of a
 * "dirty" page) when the cache size limit has been reached.
 *
 * Contrary to GDALDatasetGetVirtualMem(), pixels will be organized by tiles
 * instead of scanlines. Different ways of organizing pixel within/across tiles
 * can be selected with the eTileOrganization parameter.
 *
 * If nXSize is not a multiple of nTileXSize or nYSize is not a multiple of
 * nTileYSize, partial tiles will exists at the right and/or bottom of the
 * region of interest. Those partial tiles will also have nTileXSize *
 * nTileYSize dimension, with padding pixels.
 *
 * The pointer to access the virtual memory object is obtained with
 * CPLVirtualMemGetAddr(). It remains valid until CPLVirtualMemFree() is called.
 * CPLVirtualMemFree() must be called before the dataset object is destroyed.
 *
 * If p is such a pointer and base_type the C type matching eBufType, for
 * default values of spacing parameters, the element of image coordinates (x, y)
 * (relative to xOff, yOff) for band b can be accessed with:
 *  - for eTileOrganization = GTO_TIP,
 *        ((base_type*)p)[tile_number(x,y)*nBandCount*tile_size +
 *                        offset_in_tile(x,y)*nBandCount + (b-1)].
 *  - for eTileOrganization = GTO_BIT,
 *        ((base_type*)p)[(tile_number(x,y)*nBandCount +
 *                        (b-1)) * tile_size + offset_in_tile(x,y)].
 *  - for eTileOrganization = GTO_BSQ,
 *        ((base_type*)p)[(tile_number(x,y) +
 *                        (b-1)*nTilesCount) * tile_size + offset_in_tile(x,y)].
 *
 * where nTilesPerRow = ceil(nXSize / nTileXSize)
 *       nTilesPerCol = ceil(nYSize / nTileYSize)
 *       nTilesCount = nTilesPerRow * nTilesPerCol
 *       tile_number(x,y) = (y / nTileYSize) * nTilesPerRow + (x / nTileXSize)
 *       offset_in_tile(x,y) = (y % nTileYSize) * nTileXSize  + (x % nTileXSize)
 *       tile_size = nTileXSize * nTileYSize
 *
 * Note that for a single band request, all tile organizations are equivalent.
 *
 * Note that the mechanism used to transparently fill memory pages when they are
 * accessed is the same (but in a controlled way) than what occurs when a memory
 * error occurs in a program. Debugging software will generally interrupt
 * program execution when that happens. If needed, CPLVirtualMemPin() can be
 * used to avoid that by ensuring memory pages are allocated before being
 * accessed.
 *
 * The size of the region that can be mapped as a virtual memory object depends
 * on hardware and operating system limitations.
 * On Linux AMD64 platforms, the maximum value is 128 TB.
 * On Linux x86 platforms, the maximum value is 2 GB.
 *
 * Data type translation is automatically done if the data type
 * (eBufType) of the buffer is different than
 * that of the GDALRasterBand.
 *
 * @param hDS Dataset object
 *
 * @param eRWFlag Either GF_Read to read a region of data, or GF_Write to
 * write a region of data.
 *
 * @param nXOff The pixel offset to the top left corner of the region
 * of the band to be accessed.  This would be zero to start from the left side.
 *
 * @param nYOff The line offset to the top left corner of the region
 * of the band to be accessed.  This would be zero to start from the top.
 *
 * @param nXSize The width of the region of the band to be accessed in pixels.
 *
 * @param nYSize The height of the region of the band to be accessed in lines.
 *
 * @param nTileXSize the width of the tiles.
 *
 * @param nTileYSize the height of the tiles.
 *
 * @param eBufType the type of the pixel values in the data buffer. The
 * pixel values will automatically be translated to/from the GDALRasterBand
 * data type as needed.
 *
 * @param nBandCount the number of bands being read or written.
 *
 * @param panBandMap the list of nBandCount band numbers being read/written.
 * Note band numbers are 1 based. This may be NULL to select the first
 * nBandCount bands.
 *
 * @param eTileOrganization tile organization.
 *
 * @param nCacheSize   size in bytes of the maximum memory that will be really
 *                     allocated (must ideally fit into RAM)
 *
 * @param bSingleThreadUsage set to TRUE if there will be no concurrent threads
 *                           that will access the virtual memory mapping. This
 *                           can optimize performance a bit. If set to FALSE,
 *                           CPLVirtualMemDeclareThread() must be called.
 *
 * @param papszOptions NULL terminated list of options. Unused for now.
 *
 * @return a virtual memory object that must be freed by CPLVirtualMemFree(),
 *         or NULL in case of failure.
 *
 * @since GDAL 1.11
 */

CPLVirtualMem *GDALDatasetGetTiledVirtualMem(
    GDALDatasetH hDS, GDALRWFlag eRWFlag, int nXOff, int nYOff, int nXSize,
    int nYSize, int nTileXSize, int nTileYSize, GDALDataType eBufType,
    int nBandCount, int *panBandMap, GDALTileOrganization eTileOrganization,
    size_t nCacheSize, int bSingleThreadUsage, CSLConstList papszOptions)
{
    return GDALGetTiledVirtualMem(hDS, nullptr, eRWFlag, nXOff, nYOff, nXSize,
                                  nYSize, nTileXSize, nTileYSize, eBufType,
                                  nBandCount, panBandMap, eTileOrganization,
                                  nCacheSize, bSingleThreadUsage, papszOptions);
}

/************************************************************************/
/*                   GDALRasterBandGetTiledVirtualMem()                 */
/************************************************************************/

/** Create a CPLVirtualMem object from a GDAL rasterband object, with tiling
 * organization
 *
 * Only supported on Linux for now.
 *
 * This method allows creating a virtual memory object for a region of one
 * GDALRasterBand. The content of the virtual
 * memory object is automatically filled from dataset content when a virtual
 * memory page is first accessed, and it is released (or flushed in case of a
 * "dirty" page) when the cache size limit has been reached.
 *
 * Contrary to GDALDatasetGetVirtualMem(), pixels will be organized by tiles
 * instead of scanlines.
 *
 * If nXSize is not a multiple of nTileXSize or nYSize is not a multiple of
 * nTileYSize, partial tiles will exists at the right and/or bottom of the
 * region of interest. Those partial tiles will also have nTileXSize *
 * nTileYSize dimension, with padding pixels.
 *
 * The pointer to access the virtual memory object is obtained with
 * CPLVirtualMemGetAddr(). It remains valid until CPLVirtualMemFree() is called.
 * CPLVirtualMemFree() must be called before the raster band object is
 * destroyed.
 *
 * If p is such a pointer and base_type the C type matching eBufType, for
 * default values of spacing parameters, the element of image coordinates (x, y)
 * (relative to xOff, yOff) can be accessed with:
 *  ((base_type*)p)[tile_number(x,y)*tile_size + offset_in_tile(x,y)].
 *
 * where nTilesPerRow = ceil(nXSize / nTileXSize)
 *       nTilesCount = nTilesPerRow * nTilesPerCol
 *       tile_number(x,y) = (y / nTileYSize) * nTilesPerRow + (x / nTileXSize)
 *       offset_in_tile(x,y) = (y % nTileYSize) * nTileXSize  + (x % nTileXSize)
 *       tile_size = nTileXSize * nTileYSize
 *
 * Note that the mechanism used to transparently fill memory pages when they are
 * accessed is the same (but in a controlled way) than what occurs when a memory
 * error occurs in a program. Debugging software will generally interrupt
 * program execution when that happens. If needed, CPLVirtualMemPin() can be
 * used to avoid that by ensuring memory pages are allocated before being
 * accessed.
 *
 * The size of the region that can be mapped as a virtual memory object depends
 * on hardware and operating system limitations.
 * On Linux AMD64 platforms, the maximum value is 128 TB.
 * On Linux x86 platforms, the maximum value is 2 GB.
 *
 * Data type translation is automatically done if the data type
 * (eBufType) of the buffer is different than
 * that of the GDALRasterBand.
 *
 * @param hBand Rasterband object
 *
 * @param eRWFlag Either GF_Read to read a region of data, or GF_Write to
 * write a region of data.
 *
 * @param nXOff The pixel offset to the top left corner of the region
 * of the band to be accessed.  This would be zero to start from the left side.
 *
 * @param nYOff The line offset to the top left corner of the region
 * of the band to be accessed.  This would be zero to start from the top.
 *
 * @param nXSize The width of the region of the band to be accessed in pixels.
 *
 * @param nYSize The height of the region of the band to be accessed in lines.
 *
 * @param nTileXSize the width of the tiles.
 *
 * @param nTileYSize the height of the tiles.
 *
 * @param eBufType the type of the pixel values in the data buffer. The
 * pixel values will automatically be translated to/from the GDALRasterBand
 * data type as needed.
 *
 * @param nCacheSize   size in bytes of the maximum memory that will be really
 *                     allocated (must ideally fit into RAM)
 *
 * @param bSingleThreadUsage set to TRUE if there will be no concurrent threads
 *                           that will access the virtual memory mapping. This
 *                           can optimize performance a bit. If set to FALSE,
 *                           CPLVirtualMemDeclareThread() must be called.
 *
 * @param papszOptions NULL terminated list of options. Unused for now.
 *
 * @return a virtual memory object that must be freed by CPLVirtualMemFree(),
 *         or NULL in case of failure.
 *
 * @since GDAL 1.11
 */

CPLVirtualMem *GDALRasterBandGetTiledVirtualMem(
    GDALRasterBandH hBand, GDALRWFlag eRWFlag, int nXOff, int nYOff, int nXSize,
    int nYSize, int nTileXSize, int nTileYSize, GDALDataType eBufType,
    size_t nCacheSize, int bSingleThreadUsage, CSLConstList papszOptions)
{
    return GDALGetTiledVirtualMem(nullptr, hBand, eRWFlag, nXOff, nYOff, nXSize,
                                  nYSize, nTileXSize, nTileYSize, eBufType, 1,
                                  nullptr, GTO_BSQ, nCacheSize,
                                  bSingleThreadUsage, papszOptions);
}
